Conceptual study on using Doppler backscattering to measure magnetic pitch angle in tokamak plasmas

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Conceptual study on using Doppler backscattering to measure magnetic pitch angle in tokamak plasmas
Title:
Conceptual study on using Doppler backscattering to measure magnetic pitch angle in tokamak plasmas
Journal Title:
Nuclear Fusion
Keywords:
Publication Date:
20 October 2025
Citation:
Yeoh, A. K., Hall-Chen, V. H., Pratt, Q. T., Victor, B. S., Damba, J., Rhodes, T. L., Crocker, N. A., Fong, K. R., Hillesheim, J. C., Parra, F. I., & Ruiz Ruiz, J. (2025). Conceptual study on using Doppler backscattering to measure magnetic pitch angle in tokamak plasmas. Nuclear Fusion, 66(1), 16052. https://doi.org/10.1088/1741-4326/ae1518
Abstract:
We introduce a new approach to measure the magnetic pitch angle profile in tokamak plasmas with Doppler backscattering (DBS), a technique traditionally used for measuring flows and density fluctuations. The DBS signal is maximised when its probe beam’s wavevector is perpendicular to the magnetic field at the cutoff location, independent of the density fluctuations (Hillesheim et al 2015 Nucl. Fusion 55 073024). Hence, if one could isolate this effect, DBS would then yield information about the magnetic pitch angle. By varying the toroidal launch angle, the DBS beam reaches cutoff with different angles with respect to the magnetic field, but with other properties remaining similar. Hence, the toroidal launch angle which gives maximum backscattered power is thus that which is matched to the pitch angle at the cutoff location, enabling inference of the magnetic pitch angle. We performed systematic scans of the DBS toroidal launch angle for repeated DIII-D tokamak discharges. Experimental DBS data from this scan were analysed and combined with Gaussian beam-tracing simulations using the Scotty code (Hall-Chen et al 2022 Plasma Phys. Control. Fusion 64 095002). The pitch-angle inferred from DBS is consistent with that from magnetics-only and motional-Stark-effect-constrained (MSE) equilibrium reconstruction in the edge. In the core, the pitch angles from DBS and magnetics-only reconstructions differ by one to two degrees, while simultaneous MSE measurements were not available. The uncertainty in these measurements was under a degree; we show that this uncertainty is primarily due to the error in toroidal steering, the number of toroidally separated measurements, and shot-to-shot repeatability. We find that the error of pitch-angle measurements can be reduced by optimising the poloidal launch angle and initial beam properties. Since DBS has high spatial and temporal resolutions, is non-perturbative, does not require neutral beams, and is likely robust to neutron damage of and debris on the first mirrors, using DBS to measure the pitch angle in future fusion energy systems is especially appealing.
License type:
Attribution 4.0 International (CC BY 4.0)
Funding Info:
This research is supported by core funding from: Future Energy Acceleration & Translation (FEAT) Programme, Strategic Research and Translational Thrusts
Grant Reference no. : NA
Description:
Original content from this work may be used under the terms of the Creative Commons Attribution 4.0 license. Any further distribution of this work must maintain attribution to the author(s) and the title of the work, journal citation and DOI.
ISSN:
0029-5515
1741-4326